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PDBsum entry 2iof
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References listed in PDB file
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Key reference
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Title
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Diversification of function in the haloacid dehalogenase enzyme superfamily: the role of the cap domain in hydrolytic phosphoruscarbon bond cleavage.
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Authors
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S.D.Lahiri,
G.Zhang,
D.Dunaway-Mariano,
K.N.Allen.
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Ref.
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Bioorg Chem, 2006,
34,
394-409.
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PubMed id
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Abstract
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Phosphonatase functions in the 2-aminoethylphosphonate (AEP) degradation pathway
of bacteria, catalyzing the hydrolysis of the C-P bond in phosphonoacetaldehyde
(Pald) via formation of a bi-covalent Lys53ethylenamine/Asp12 aspartylphosphate
intermediate. Because phosphonatase is a member of the haloacid dehalogenase
superfamily, a family predominantly comprised of phosphatases, the question
arises as to how this new catalytic activity evolved. The source of general
acid-base catalysis for Schiff-base formation and aspartylphosphate hydrolysis
was probed using pH-rate profile analysis of active-site mutants and X-ray
crystallographic analysis of modified forms of the enzyme. The 2.9 A X-ray
crystal structure of the mutant Lys53Arg complexed with Mg2+ and phosphate shows
that the equilibrium between the open and the closed conformation is disrupted,
favoring the open conformation. Thus, proton dissociation from the cap domain
Lys53 is required for cap domain-core domain closure. The likely recipient of
the Lys53 proton is a water-His56 pair that serves to relay the proton to the
carbonyl oxygen of the phosphonoacetaldehyde (Pald) substrate upon addition of
the Lys53. The pH-rate profile analysis of active-site mutants was carried out
to test this proposal. The proximal core domain residues Cys22 and Tyr128 were
ruled out, and the role of cap domain His56 was supported by the results. The
X-ray crystallographic structure of wild-type phosphonatase reduced with NaBH4
in the presence of Pald was determined at 2.4A resolution to reveal N
epsilon-ethyl-Lys53 juxtaposed with a sulfate ligand bound in the phosphate
site. The position of the C2 of the N-ethyl group in this structure is
consistent with the hypothesis that the cap domain N epsilon-ethylenamine-Lys53
functions as a general base in the hydrolysis of the aspartylphosphate
bi-covalent enzyme intermediate. Because the enzyme residues proposed to play a
key role in P-C bond cleavage are localized on the cap domain, this domain
appears to have evolved to support the diversification of the HAD phosphatase
core domain for catalysis of hydrolytic P-C bond cleavage.
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